JP2016173326A - Timing signal generator and electronic apparatus - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a timing signal generator and an electronic apparatus that can ensure a time-variant accuracy of a reference signal.SOLUTION: A timing signal generator 1 includes: an output terminal outputting a reference signal; a first reference signal generation unit generating a first reference signal based on the reference signal input from the outside; a second reference signal generation unit generating a second reference signal based on a signal output from an oscillator 30; and a control unit 31 switching the reference signal to be output from an output terminal, from the first reference signal to the second reference signal based on preliminary information indicating deterioration of accuracy of the reference signal.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a timing signal generator and an electronic apparatus.

  A GPS (Global Positioning System) that is one of Global Navigation Satellite System (GNSS) using an artificial satellite is widely known. A GPS satellite used for GPS is equipped with an extremely accurate atomic clock, and transmits a satellite signal on which orbit information, accurate time information, and the like of the GPS satellite are superimposed on the ground. A satellite signal transmitted from a GPS satellite is received by a GPS receiver. The GPS receiver is synchronized with a process of calculating the current position and time information of the GPS receiver based on orbit information and time information superimposed on the satellite signal, and Coordinated Universal Time (UTC). A process for generating an accurate timing signal (1PPS) is performed.

  Such a GPS receiver is provided with a normal positioning (position estimation) mode for providing position and time based on positioning calculation and a position fixing mode for providing time by fixed position positioning at a known position. It is common.

  In the normal positioning mode, satellite signals from GPS satellites of a predetermined number (minimum of three for two-dimensional positioning or four for three-dimensional positioning) or more are required. Also, the greater the number of GPS satellites that can receive satellite signals, the more accurate the positioning calculation.

  In the fixed position mode, if position information of a GPS receiver is set, 1 PPS can be generated if a satellite signal from at least one GPS satellite can be received.

  Patent Document 1 discloses a one-second signal acquisition device that receives ranging radio waves transmitted from a plurality of artificial satellites and generates 1 PPS (reference signal).

  This 1-second signal acquisition device includes an antenna 2 that receives ranging radio waves transmitted from a plurality of artificial satellites 1, a GPS receiver 3 that is connected to the antenna 2, and a 1PPS that is connected to the GPS receiver 3. A validity determination unit 4, a state determination unit 5 connected to the GPS receiver 3 and the 1PPS validity determination unit 4, and a timing circuit 6 connected to the 1PPS validity determination unit 4 and the state determination unit 5 And an in-device reference oscillator 7 connected to the timing circuit 6, the 1PPS validity determination unit 4 and the state determination unit 5. The timing circuit 6 includes a load side device 8 such as a time-related device. Is connected. The 1PPS validity determination unit 4 determines the validity of 1PPS output from the GPS receiver 3, that is, whether or not the 1PPS is continuous at the correct 1 Hz timing.

  The 1-second signal acquisition device outputs 1 PPS output from the GPS receiver 3 when the 1PPS is valid, and outputs 1 PPS output from the in-device reference oscillator 7 when the 1 PPS is not valid.

JP-A-8-105984

  However, in the 1-second signal acquisition device described in Patent Document 1, while it is determined whether 1 PPS output from the GPS receiver 3 is valid, the GPS receiver 3 is not valid. There is a case where 1PPS output from the 1PPS is output, and there is a problem that the accuracy of 1PPS cannot be guaranteed.

  An object of the present invention is to provide a timing signal generator and an electronic apparatus that can guarantee the temporal accuracy of a reference signal.

  SUMMARY An advantage of some aspects of the invention is to solve at least a part of the problems described above, and the invention can be implemented as the following forms or application examples.

[Application Example 1]
The timing signal generator of the present invention includes an output terminal for outputting a reference signal,
A first reference signal generation unit that generates a first reference signal based on a reference signal input from the outside;
A second reference signal generator that generates a second reference signal based on a signal output from the oscillator;
A control unit that switches the reference signal output from the output terminal from the first reference signal to the second reference signal based on prior information indicating that the accuracy of the reference signal is reduced;
It is characterized by providing.

  As a result, the reference signal can be switched from the first reference signal to the second reference signal before the accuracy of the reference signal falls below the lower limit value of the allowable range, thereby ensuring the temporal accuracy of the reference signal. be able to.

[Application Example 2]
In the timing signal generator of the present invention, it is preferable that the timing signal generator includes a prior information output unit that outputs the prior information to the control unit.

  Accordingly, the control unit can switch the reference signal from the first reference signal to the second reference signal before the accuracy of the reference signal falls below the lower limit value of the allowable range based on the prior information.

[Application Example 3]
In the timing signal generator of the present invention, it is preferable that the prior information output unit includes a prior information storage unit that stores the prior information.

  Thereby, the time and effort of inputting prior information each time can be saved by using the prior information stored in the prior information storage unit.

[Application Example 4]
In the timing signal generator of the present invention, it is preferable that the prior information output unit includes a prior information generation unit that generates the prior information based on the reference signal in advance.
Thereby, more accurate prior information can be obtained.

[Application Example 5]
The timing signal generator of the present invention has a time information storage unit for storing time information,
It is preferable that the control unit includes a switching timing determination unit that determines a switching timing of the reference signal based on the prior information and the time information.

  Thereby, the reference signal switching timing can be arbitrarily set before the accuracy of the reference signal falls below the lower limit value of the allowable range.

[Application Example 6]
In the timing signal generator of the present invention, the reference signal is a satellite signal transmitted from a position information satellite,
The prior information output unit, as information indicating that the accuracy of the reference signal is decreased, DOP information indicating a relationship between a positioning accuracy decrease rate based on the reference signal and time is directed to the switching timing determination unit. Output,
Preferably, the switching timing determination unit includes a threshold value storage unit that stores a threshold value, and determines the switching timing of the reference signal based on the threshold value and the DOP information.

  Thereby, it is possible to arbitrarily set how much the accuracy reduction rate of positioning based on the reference signal is to be output as the reference signal until it becomes a value.

[Application Example 7]
In the timing signal generator of the present invention, the oscillator is a voltage controlled oscillator,
The first reference signal generation unit is configured to input a control voltage of the oscillator to the oscillator based on the reference signal when the accuracy reduction rate is equal to or less than the threshold, and to generate the first reference signal,
The control unit obtains information on the control voltage of the oscillator input to the oscillator when the accuracy reduction rate is equal to or less than the threshold, and when the accuracy reduction rate exceeds the threshold, Based on the acquired control voltage information, a control voltage input to the oscillator is obtained, and the obtained control voltage is inputted to the oscillator, whereby the reference signal output from the output terminal is derived from the first reference signal. It is preferable to switch to the second reference signal.

  Thereby, when outputting the second reference signal, the aging correction of the oscillator can be performed, and the temporal accuracy of the second reference signal can be improved.

[Application Example 8]
In the timing signal generator of the present invention, the reference signal is a satellite signal transmitted from a position information satellite,
The first reference signal generator preferably includes a receiver that receives the satellite signal.
Thereby, the satellite signal is received and the first reference signal can be generated.

[Application Example 9]
In the timing signal generator of the present invention, the prior information includes information indicating that the accuracy of the reference signal is improved,
The control unit preferably switches the reference signal output from the output terminal from the second reference signal to the first reference signal based on the prior information.

  As a result, when the accuracy of the reference signal falls below the lower limit value of the allowable range and then becomes equal to or higher than the lower limit value, the reference signal can be switched from the second reference signal to the first reference signal. The temporal accuracy of the signal can be further improved.

[Application Example 10]
The timing signal generator according to the present invention outputs a signal used for generating a reference signal from the reference signal from an internal oscillator based on prior information indicating that the accuracy of the reference signal input from the outside decreases. It is characterized by switching to a signal.

  As a result, the reference signal can be switched from the first reference signal to the second reference signal before the accuracy of the reference signal falls below the lower limit value of the allowable range, thereby ensuring the temporal accuracy of the reference signal. be able to.

[Application Example 11]
An electronic apparatus according to the present invention includes the timing signal generator according to the present invention.

  As a result, the reference signal can be switched from the first reference signal to the second reference signal before the accuracy of the reference signal falls below the lower limit value of the allowable range, thereby ensuring the temporal accuracy of the reference signal. be able to.

It is a figure which shows schematic structure of 1st Embodiment of the timing signal generator of this invention. It is a figure which shows the structure of the navigation message transmitted from a GPS satellite. It is a block diagram which shows the structural example of the GPS receiver with which the timing signal generator shown in FIG. 1 is provided. It is a graph which shows the relationship between the precision fall rate of a satellite signal, and time in the timing signal generator shown in FIG. 2 is a graph showing a relationship between a control voltage input to a crystal oscillator obtained based on a satellite signal and time in the timing signal generator shown in FIG. 1. It is a figure which shows schematic structure of the principal part of 2nd Embodiment of the timing signal generator of this invention. It is a graph which shows the relationship between the precision fall rate of a satellite signal, and time in the timing signal generator shown in FIG. It is a block diagram which shows embodiment of the electronic device of this invention.

  DESCRIPTION OF EMBODIMENTS Hereinafter, a timing signal generator and an electronic apparatus according to the present invention will be described in detail based on embodiments shown in the accompanying drawings.

1. Timing Signal Generator <First Embodiment>
FIG. 1 is a diagram showing a schematic configuration of a first embodiment of a timing signal generator of the present invention. FIG. 2 is a diagram showing a configuration of a navigation message transmitted from a GPS satellite. FIG. 3 is a block diagram showing a configuration example of a GPS receiver included in the timing signal generator shown in FIG. FIG. 4 is a graph showing the relationship between the satellite signal accuracy reduction rate and time in the timing signal generator shown in FIG. FIG. 5 is a graph showing the relationship between the control voltage input to the crystal oscillator obtained based on the satellite signal and time in the timing signal generator shown in FIG.

  A timing signal generator 1 shown in FIG. 1 includes a GPS receiver (receiver) 10 as a satellite signal receiver, a processing unit (CPU) 20 as a satellite signal reception controller, and a voltage-controlled oscillator (VCO). A crystal oscillator (oscillator) 30, a temperature sensor 40, a control unit 31, a timer (clock) 32, a prior information output unit 33, and a GPS antenna 50 are provided.

  Note that the timing signal generation device 1 may be partially or entirely physically separated from each other, or may be integrated. For example, the GPS receiver 10 and the processing unit 20 may be realized by separate ICs, or the GPS receiver 10 and the processing unit 20 may be realized as a one-chip IC. The other parts are the same.

  The timing signal generator 1 receives a signal transmitted from a GPS satellite (position information satellite) 2 and generates a highly accurate 1PPS.

  The GPS satellite 2 orbits a predetermined orbit above the earth, and superimposes a navigation message and a C / A code (Coarse / Acquisition Code) on a 1.57542 GHz radio wave (L1 wave) that is a carrier wave (with a carrier wave). The modulated satellite signal (GPS signal) is transmitted to the ground. The satellite signal is an example of a reference signal input to the timing signal generator 1 from the outside.

  The C / A code is for identifying satellite signals of about 30 GPS satellites that are presently present, and is a unique pattern consisting of 1023 chips (1 ms period) in which each chip is either +1 or -1. is there. Therefore, by correlating the satellite signal and the pattern of each C / A code, the C / A code superimposed on the satellite signal can be detected.

  The satellite signal (specifically, navigation message) transmitted by each GPS satellite 2 includes orbit information indicating the position of each GPS satellite 2 on the orbit. Each GPS satellite 2 has an atomic clock, and the satellite signal includes extremely accurate time information measured by the atomic clock. Therefore, by receiving satellite signals from four or more GPS satellites 2 and performing positioning calculation using orbit information and time information included in each satellite signal, a reception point (location where the GPS antenna 50 is installed) Accurate information on the location and time can be obtained. Specifically, a four-dimensional equation having four variables as the three-dimensional position (x, y, z) and time t of the reception point may be established to find the solution.

  When the position of the reception point is known, the satellite signal from one or more GPS satellites 2 can be received, and the time information of the reception point can be obtained using the time information included in each satellite signal. .

  Also, information on the difference between the time of each GPS satellite 2 and the time of the reception point can be obtained using the orbit information included in each satellite signal. A slight time error of the atomic clock mounted on each GPS satellite 2 is measured by the control segment on the ground, and the satellite signal includes a time correction parameter for correcting the time error. By correcting the time at the reception point using this time correction parameter, it is possible to obtain extremely accurate time information.

  As shown in FIG. 2 (A), the navigation message is configured as data with a main frame having a total number of 1500 bits as one unit. The main frame is divided into five sub-frames 1 to 5 each having 300 bits. Data of one subframe is transmitted from each GPS satellite 2 in 6 seconds. Accordingly, data of one main frame is transmitted from each GPS satellite 2 in 30 seconds.

  Subframe 1 includes satellite correction data such as week number data (WN). The week number data is information representing a week including the time of the GPS satellite 2. The starting time of the GPS satellite 2 is UTC (Universal Standard Time) on January 6, 1980, 00:00:00, and the week starting on this day has a week number 0. Week number data is updated on a weekly basis.

  The subframes 2 and 3 include ephemeris parameters (detailed orbit information of each GPS satellite 2). The subframes 4 and 5 include almanac parameters (general orbit information of all GPS satellites 2).

  Furthermore, at each head of subframes 1 to 5, a TLM (Telemetry) word storing 30-bit TLM (Telemetry word) data, and a HOW word storing 30-bit HOW (hand over word) data, It is included.

  Therefore, TLM words and HOW words are transmitted from the GPS satellite 2 at intervals of 6 seconds, whereas satellite correction data such as week number data, ephemeris parameters, and almanac parameters are transmitted at intervals of 30 seconds.

  As shown in FIG. 2B, the TLM word includes preamble data, a TLM message, a reserved bit, and parity data.

  As shown in FIG. 2C, the HOW word includes time information called TOW (Time of Week) (hereinafter also referred to as “Z count”). In the Z count data, the elapsed time from 0 o'clock every Sunday is displayed in seconds, and it returns to 0 at 0 o'clock on the next Sunday. That is, the Z count data is information in seconds indicated every week from the beginning of the week, and the elapsed time is a number expressed in units of 1.5 seconds. Here, the Z count data indicates time information at which the first bit of the next subframe data is transmitted. For example, the Z count data of subframe 1 indicates time information at which the first bit of subframe 2 is transmitted. The HOW word also includes 3-bit data (ID code) indicating the ID of the subframe. That is, ID codes “001”, “010”, “011”, “100”, and “101” are included in the HOW words of subframes 1 to 5 shown in FIG.

  By acquiring the week number data included in subframe 1 and the HOW word (Z count data) included in subframes 1 to 5, the time of GPS satellite 2 can be calculated. If the week number data is acquired previously and the elapsed time from the time when the week number data was acquired is counted internally, the current week number data of the GPS satellite 2 can be obtained without acquiring the week number data every time. Can be obtained. Therefore, if only the Z count data is acquired, the current time of the GPS satellite 2 can be known roughly.

  The satellite signal as described above is received by the GPS receiver 10 via the GPS antenna 50 shown in FIG.

  The GPS antenna 50 is an antenna that receives various radio waves including satellite signals, and is connected to the GPS receiver 10.

  The GPS receiver 10 performs various processes based on the satellite signal received via the GPS antenna 50.

  More specifically, the GPS receiver 10 has a normal positioning mode (first mode) and a fixed position mode (second mode), and a control command (mode setting command) from the processing unit (CPU) 20. In accordance with the control command), either the normal positioning mode or the fixed position mode is set.

  The GPS receiver 10 functions as a “positioning calculation unit” in the normal positioning mode, receives satellite signals transmitted from a plurality of (preferably four or more) GPS satellites 2, and includes orbits included in the received satellite signals. Positioning calculation is performed based on information (specifically, the above-described ephemeris data, almanac data, etc.) and time information (specifically, the above-described week number data, Z count data, etc.). The GPS receiver 10 generates the following 1PPS.

  The GPS receiver 10 functions as a “timing signal generation unit” in the position fixing mode, receives a satellite signal transmitted from at least one GPS satellite 2, and orbit information and time included in the received satellite signal. Based on the information and the position information of the set reception point, 1 PPS (1 Pulse Per Second) is generated. 1 PPS (an example of a timing signal synchronized with a reference time) is a pulse signal that is completely synchronized with UTC (Universal Standard Time), and includes one pulse per second. As described above, since the satellite signal used by the GPS receiver 10 for generating the timing signal includes the orbit information and the time information, a timing signal accurately synchronized with the reference time can be generated.

Hereinafter, the configuration of the GPS receiver 10 will be described in detail.
The GPS receiver 10 shown in FIG. 3 has a SAW (Surface Acoustic Wave) filter 11, an RF processing unit 12, a baseband processing unit 13, and a temperature compensated crystal oscillator (TCXO) 14. doing.

  The SAW filter 11 performs a process of extracting a satellite signal from the radio wave received by the GPS antenna 50. The SAW filter 11 is configured as a bandpass filter that passes a 1.5 GHz band signal.

  The RF processing unit 12 includes a PLL (Phase Locked Loop) 121, an LNA (Low Noise Amplifier) 122, a mixer 123, an IF amplifier 124, an IF (Intermediate Frequency) filter 125, and an ADC (A / D converter) 126. Have.

  The PLL 121 generates a clock signal obtained by multiplying the oscillation signal of the TCXO 14 that oscillates at about several tens of MHz to a frequency of 1.5 GHz band.

  The satellite signal extracted by the SAW filter 11 is amplified by the LNA 122. The satellite signal amplified by the LNA 122 is mixed with the clock signal output from the PLL 121 by the mixer 123 and down-converted to an intermediate frequency band (for example, several MHz) signal (IF signal). The signal mixed by the mixer 123 is amplified by the IF amplifier 124.

  Since the mixer 123 generates a high-frequency signal in the order of GHz along with the IF signal, the IF amplifier 124 amplifies the high-frequency signal together with the IF signal. The IF filter 125 passes the IF signal and removes the high-frequency signal (precisely, it is attenuated below a predetermined level). The IF signal that has passed through the IF filter 125 is converted into a digital signal by an ADC (A / D converter) 126.

  The baseband processing unit 13 includes a DSP (Digital Signal Processor) 131, a CPU (Central Processing Unit) 132, an SRAM (Static Random Access Memory) 133, and an RTC (Real Time Clock) 134, and the oscillation signal of the TCXO 14 is clocked. Various processing is performed as a signal.

  The DSP 131 and the CPU 132 cooperate with each other to demodulate the baseband signal from the IF signal, acquire trajectory information and time information included in the navigation message, and perform processing in the normal positioning mode or position fixing mode.

  The SRAM 133 stores time information and orbit information acquired, position information of a reception point set in accordance with a predetermined control command (position setting control command), an elevation angle mask used in a position fixing mode, and the like. Is. The RTC 134 generates timing for performing baseband processing. The RTC 134 is counted up by the clock signal from the TCXO 14.

  Specifically, the baseband processing unit 13 generates a local code having the same pattern as each C / A code, and performs a process (satellite search) for correlating each C / A code included in the baseband signal with the local code. )I do. Then, the baseband processing unit 13 adjusts the local code generation timing so that the correlation value for each local code has a peak, and when the correlation value is equal to or greater than the threshold, the local code is set as the C / A code. It is determined that the GPS satellite 2 is synchronized (GPS satellite 2 is captured). Note that GPS employs a CDMA (Code Division Multiple Access) system in which all GPS satellites 2 transmit satellite signals of the same frequency using different C / A codes. Therefore, it is possible to search for a GPS satellite 2 that can be captured by determining the C / A code included in the received satellite signal.

  Further, the baseband processing unit 13 mixes a local code and a baseband signal having the same pattern as the C / A code of the GPS satellite 2 in order to acquire the orbit information and time information of the captured GPS satellite 2. I do. A navigation message including the orbit information and time information of the captured GPS satellite 2 is demodulated in the mixed signal. Then, the baseband processing unit 13 performs processing for acquiring trajectory information and time information included in the navigation message and storing them in the SRAM 133.

  The baseband processing unit 13 receives a predetermined control command (specifically, a mode setting control command), and is set to either the normal positioning mode or the position fixing mode. In the normal positioning mode, the baseband processing unit 13 performs positioning calculation using orbit information and time information of four or more GPS satellites 2 stored in the SRAM 133.

  Further, the baseband processing unit 13 uses the orbit information of one or more GPS satellites 2 stored in the SRAM 133 and the position information of the reception points stored in the SRAM 133 in the position fixing mode. 1PPS is output. Specifically, the baseband processing unit 13 includes a 1PPS counter that counts the generation timing of each 1PPS pulse in a part of the RTC 134, and uses the orbit information of the GPS satellite 2 and the position information of the reception point. The propagation delay time required for the satellite signal transmitted from the GPS satellite 2 to reach the reception point is calculated, and the set value of the 1PPS counter is changed to the optimum value based on this propagation delay time.

  In the normal positioning mode, the baseband processing unit 13 outputs 1 PPS based on the reception point time information obtained by the positioning calculation.

  In the position fixing mode, positioning calculation may be performed if a plurality of GPS satellites 2 can be captured.

  In addition, the baseband processing unit 13 outputs NMEA data including various information such as position information and time information as a result of positioning calculation, reception status (number of GPS satellites 2 captured, satellite signal strength, etc.).

  The operation of the GPS receiver 10 configured as described above is controlled by the processing unit (CPU) 20 shown in FIG.

  The processing unit 20 transmits various control commands to the GPS receiver 10 to control the operation of the GPS receiver 10, receives 1PPS and NMEA data output from the GPS receiver 10, and performs various processes. The processing unit 20 may perform various processes according to a program stored in an arbitrary memory, for example.

  The processing unit 20 includes a phase comparator 21, a loop filter 22, a DSP (Digital Signal Processor) (position information generation unit) 23, a frequency divider 24, and a GPS control unit (reception control unit) 25. Note that the DSP 23 and the GPS control unit 25 may be composed of a single component.

  The DSP 23 periodically acquires NMEA data from the GPS receiver 10 (for example, every second) and collects position information (results of positioning calculation in the normal positioning mode by the GPS receiver 10) included in the NMEA data. Then, statistical information for a predetermined time is generated, and processing for generating position information of the reception point is performed based on the statistical information. In particular, the position information of the reception point is generated based on representative values (for example, an average value, a mode value, or a median value) of a plurality of positioning calculation results in the normal positioning mode by the GPS receiver 10.

  The GPS control unit 25 transmits various control commands to the GPS receiver 10 and controls the operation of the GPS receiver 10. Specifically, the GPS control unit 25 transmits a mode setting control command to the GPS receiver 10 and performs a process of switching the GPS receiver 10 from the normal positioning mode to the position fixing mode. Further, the GPS control unit 25 transmits a position setting control command to the GPS receiver 10 before switching the GPS receiver 10 from the normal positioning mode to the position fixing mode, and receives the position information of the reception point generated by the DSP 23. Processing to set in the GPS receiver 10 is performed.

  The frequency divider 24 divides the clock signal (frequency: f) output from the crystal oscillator 30 by f and outputs a 1 Hz frequency-divided clock signal.

  The phase comparator 21 compares the phase of the 1PPS output from the GPS receiver 10 with the 1 Hz frequency-divided clock signal output from the frequency divider 24. The phase difference signal as a comparison result of the phase comparator 21 is input to the crystal oscillator 30 via the loop filter 22. The parameters of the loop filter 22 are set by the DSP 23.

  The 1 Hz frequency-divided clock signal output from the frequency divider 24 is synchronized with 1 PPS output from the GPS receiver 10, and the timing signal generator 1 synchronizes this frequency-divided clock signal with UTC with extremely high frequency accuracy. Output to the outside as high 1PPS. This 1PPS is referred to as a “first reference signal”. The GPS receiver 10, the processing unit 20, and the crystal oscillator 30 constitute the main part of the first reference signal generation unit.

  Further, under the control of the control unit 31, the processing unit 20 stops the process of synchronizing the clock signal output from the crystal oscillator 30 with 1PPS output from the GPS receiver 10, and stops the output of the first reference signal, Instead of the first reference signal, the crystal oscillator 30 is oscillated free-running to output 1 PPS to the outside. This 1PPS is referred to as a “second reference signal”. The crystal oscillator 30 and the frequency divider 24 constitute a main part of the second reference signal generation unit.

  The switching between the first reference signal and the second reference signal is performed based on prior information described later, which will be described in detail later.

  In addition, unexpectedly, when a situation (holdover) occurs such that the GPS receiver 10 cannot receive a satellite signal, the accuracy of 1 PPS output from the GPS receiver 10 deteriorates, or the GPS receiver 10 has 1 PPS. Although the output is stopped, the second reference signal may be output in such a case.

  Further, the timing signal generator 1 outputs the latest NMEA data to the outside every second in synchronization with 1 PPS, and also outputs a clock signal having a frequency f output from the crystal oscillator 30 to the outside.

  The crystal oscillator 30 is not particularly limited, and examples thereof include a thermostat crystal oscillator (OCXO) and a temperature compensated crystal oscillator (TCXO). In the present embodiment, the crystal oscillator 30 is used as the oscillator. However, the present invention is not limited to this. For example, an atomic oscillator or the like may be used as the oscillator.

  The crystal oscillator 30 is configured so that the frequency can be finely adjusted according to the output voltage (control voltage) of the loop filter 22, and as described above, the phase comparator 21, the loop filter 22, the DSP 23, and the frequency divider 24. The clock signal output from the crystal oscillator 30 is completely synchronized with 1 PPS output from the GPS receiver 10. That is, the configuration of the phase comparator 21, the loop filter 22, the DSP 23, and the frequency divider 24 functions as a “synchronization control unit” that synchronizes the clock signal output from the crystal oscillator 30 with 1 PPS. A temperature sensor 40 is disposed in the vicinity of the crystal oscillator 30, and the DSP 23 adjusts the output voltage of the phase comparator 21 in accordance with the detection value (detection temperature) of the temperature sensor 40, so that the crystal oscillator 30. The temperature temperature characteristics of the other are also subjected to temperature compensation processing.

  As illustrated in FIG. 1, the control unit 31 includes a switching timing determination unit 311, and the switching timing determination unit 311 includes a threshold storage unit 312. The control unit 31 includes, for example, a CPU, a memory, and the like, and controls the switching operation of the processing unit 20 between the first reference signal and the second reference signal.

  The prior information output unit 33 includes a prior information generation unit 331, a prior information storage unit 332, and a time information storage unit 333. The prior information generation unit 331 includes the GPS receiver 10 described above.

  In this timing signal generation device 1, pre-information is stored in advance in the pre-information storage unit 332, and 1PPS is output to the outside from an output terminal electrically connected to the processing unit 20 based on the pre-information. (Reference signal) is switched from one of the first reference signal and the second reference signal to the other. Hereinafter, “output from an output terminal electrically connected to the processing unit 20 to the outside” is also simply referred to as “output”. “Switching from one of the first reference signal and the second reference signal to the other” is also simply referred to as “switching” or the like.

  The reason for switching the reference signal is that, for example, if the position of the GPS satellite 2 is poor, the accuracy of 1PPS output from the GPS receiver 10 is deteriorated, and the accuracy of the first reference signal is deteriorated. Therefore, when the position of the GPS satellite 2 is good, the first reference signal is output as the reference signal, and when the position of the GPS satellite 2 is bad, the second reference signal is output as the reference signal.

  Further, as the prior information, information based on the position of the GPS satellite 2 can be cited, and is information that can be obtained in advance.

  Specifically, as prior information, position information indicating the relationship between the position of the GPS satellite 2 with respect to the reception point (location where the GPS antenna 50 is installed) and time, or DOP (Division Of Precision) such as PDOP (Position Direction Of Precision). ) And time, DOP information indicating the relationship between time, and GPS receiver 10 receiving sensitivity information indicating the relationship between satellite signal reception sensitivity and time. These include information indicating that the accuracy of satellite signals such as 1PPS is reduced or improved.

  “DOP” is a numerical value (index) indicating the degree of deterioration of positioning accuracy based on satellite signals received by the GPS receiver 10, that is, a rate of accuracy reduction, and the lower the better. “PDOP” is a subordinate concept of DOP, which is a numerical value (index) indicating the degree of deterioration of positioning accuracy based on satellite signals received by the GPS receiver 10, that is, a position accuracy decrease rate, The lower the better. In the present embodiment, a case where DOP information is typically used as prior information will be described as an example. Note that the relationship between DOP and time is not constant every day, but shifts every day. Therefore, prior information such as DOP information is created in consideration of the shift.

Next, reference signal switching timing will be described.
First, a threshold value indicating the lower limit value of the allowable range of DOP is set. This threshold value is stored in advance in the threshold value storage unit 312.

  The threshold is not particularly limited and is appropriately set according to various conditions, but is preferably 3 or less, more preferably 2 or less, 1.05 or more, 1.5 or less. More preferably.

  If the threshold value is larger than the upper limit value, the accuracy of the first reference signal may be insufficient depending on other conditions.

  The prior information output unit 33 outputs DOP information toward the switching timing determination unit 311 of the control unit 31. Then, based on the DOP information and the threshold value, the switching timing determination unit 311 determines the reference signal switching timing as described below, and the control unit 31 controls the operation of the processing unit 20 to control the reference signal. Switch signals.

  As shown in FIG. 4, the times when DOP is the threshold are t2 and t3. In this case, the first reference signal is output until time t2, and is switched to the second reference signal at time t2. The second reference signal is output from time t2 to time t3, and is switched to the first reference signal at time t3. Then, the first reference signal is output from time t3.

  As described above, by switching the reference signal based on the prior information, it is possible to always output a highly accurate reference signal and to guarantee the accuracy of the reference signal.

  In this reference signal switching control, the times t2 and t3 may be stored, and the reference signals may be switched at the times t2 and t3.

  In addition, as described above, the times t2 and t3 may be used as switching times. However, in consideration of errors and the like, the reference signal is switched before a predetermined time T1 before t2 and after a predetermined time T2 after t3. Preferably it is done. Each of T1 and T2 is time information, and is stored in the time information storage unit 333 in advance.

  The prior information output unit 33 outputs DOP information and time information to the switching timing determination unit 311 of the control unit 31. Then, the switching timing determination unit 311 determines the reference signal switching timing based on the DOP information, the threshold value, and the time information as follows, and the control unit 31 controls the operation of the processing unit 20. The reference signal is switched.

  In other words, the first reference signal is output until time t1, and is switched to the second reference signal at time t1. Further, the second reference signal is output from time t1 to time t4, and is switched to the first reference signal at time t4. Then, the first reference signal is output from time t4.

  As a result, it is possible to output a highly accurate reference signal more reliably and always, and to guarantee the accuracy of the reference signal.

  Further, T1 and T2 are not particularly limited and are appropriately set according to various conditions, but are preferably 30 minutes or less, more preferably 15 minutes or less, and more preferably 1 second. More preferably, it is 5 minutes or less. T1 and T2 may be the same or different.

  If T1 and T2 are longer than the upper limit, the accuracy of the first reference signal may be insufficient depending on other conditions.

  In this reference signal switching control, the times t1 and t4 may be stored, and the reference signals may be switched at the times t1 and t4.

  In such a timing signal generator 1, the user obtains DOP information prior to its use, stores the DOP information in the prior information storage unit 332, and stores the threshold in the threshold storage unit 312. In addition, the time information is stored in the time information storage unit 333. Needless to say, any one, two, or all of these pieces of information may be stored in advance.

  Further, in this timing signal generating device 1, the timing signal generating device 1 is operated in advance, the prior information generating unit 331 generates (creates) DOP information, and the DOP information is stored in the prior information storage unit 332. You may comprise. In this case, the GPS receiver 10 generates DOP information based on the received satellite signal. As described above, since the relationship between DOP and time is not constant every day and shifts every day, the prior information generation unit 331 generates DOP information in consideration of the shift. Thereby, more accurate DOP information can be obtained.

  Further, in this timing signal generator 1, when DOP is equal to or smaller than the threshold value, information for obtaining a correction value for aging correction of the crystal oscillator 30, that is, the crystal oscillator 30 inputted from the loop filter 22 to the crystal oscillator 30. Get control voltage information. Information on the control voltage is stored in a storage unit (not shown). When the DOP exceeds the threshold, the control voltage of the crystal oscillator 30 including the correction value for the aging correction of the crystal oscillator 30 is obtained based on the control voltage information, and the control voltage is input to the crystal oscillator 30. Then, the crystal oscillator 30 oscillates freely and outputs the second reference signal to the outside. Thereby, when outputting the second reference signal, the aging correction of the crystal oscillator 30 can be performed, and the temporal accuracy of the second reference signal can be improved.

  Explaining with a specific example, as shown in FIG. 5, the control voltage information of the crystal oscillator 30 output from the loop filter 22 is acquired until time t2 when the DOP is a threshold value.

  When DOP exceeds the threshold value, that is, from time t2 to time t3, the control of the crystal oscillator 30 including the correction value of the aging correction of the crystal oscillator 30 is performed based on the control voltage information from the time t2. Find the voltage. That is, the control voltage of the crystal oscillator 30 at the corresponding time is obtained based on a function (calculation formula) representing a curve indicating the relationship between the control voltage of the crystal oscillator 30 and the time up to time t2 shown in FIG. From the time t2 to the time t3, the obtained control voltage is input to the crystal oscillator 30, the crystal oscillator 30 is caused to self-oscillate, and the second reference signal is output to the outside.

  Also, from time t3, the control voltage information of the crystal oscillator 30 output from the loop filter 22 is acquired in the same manner as described above, and when DOP exceeds the threshold value, the control voltage information is based on the control voltage information as described above. Thus, the control voltage of the crystal oscillator 30 including the correction value of the aging correction of the crystal oscillator 30 is obtained.

  As described above, the timing signal generator 1 uses the DOP information to obtain the clock signal output from the crystal oscillator 30 when the accuracy of 1 PPS output from the GPS receiver 10 is high. By synchronizing with the accurate 1PPS output from the first reference signal, it is possible to generate and output the first reference signal with higher accuracy than the accuracy of the crystal oscillator 30.

  When the accuracy of 1PPS output from the GPS receiver 10 is low, the process of synchronizing the clock signal output from the crystal oscillator 30 with 1PPS output from the GPS receiver 10 is stopped and the crystal oscillator 30 is caused to oscillate freely. Thus, at least the second reference signal having the frequency accuracy of the crystal oscillator 30 can be output.

  Moreover, since the DOP information is stored in advance in the prior information storage unit 332 and the reference signal is switched based on the DOP information, before the accuracy of 1 PPS output from the GPS receiver 10 is reduced, Switching from the first reference signal to the second reference signal can be performed. As a result, a highly accurate reference signal can be output at all times, and the accuracy of the reference signal can be guaranteed.

  In addition, since the accuracy of the reference signal can be guaranteed without arranging the antenna 50 at a high position, the cost can be reduced accordingly.

Second Embodiment
FIG. 6 is a diagram showing a schematic configuration of the main part of the second embodiment of the timing signal generator of the present invention. FIG. 7 is a graph showing the relationship between the satellite signal accuracy reduction rate and time in the timing signal generator shown in FIG.

  Hereinafter, the second embodiment will be described with a focus on the differences from the first embodiment described above, and the description of the same matters will be omitted.

  As shown in FIG. 6, in the timing signal generator 1 of the second embodiment, the GPS antenna 50 is installed on the outer surface 43 of the wall portion 42 of the building 41. The GPS antenna 50 is disposed at a position lower than the height of the building 41.

  In such a case, depending on the time zone (time), some of the radio waves transmitted from the four GPS satellites 2 may be blocked by the building 41. In the example shown in FIG. 6, during a predetermined time period, one of the radio waves transmitted from the four GPS satellites 2 is blocked by the building 41, so that one of the four satellite signals is transmitted via the antenna 50. Therefore, the GPS receiver 10 cannot receive and the DOP becomes high.

  In the timing signal generator 1, DOP information is stored in advance in the prior information storage unit 332 in consideration of the above situation as prior information, and the reference signal is switched as described in the first embodiment. As shown in FIG. 7, in the present embodiment, the DOP becomes high four times a day, and the timing signal generator 1 switches the reference signal accordingly.

  In this embodiment, instead of DOP information, for example, at least one of the four GPS satellites 2 becomes a blind spot with respect to the antenna 50 as the prior information, and satellite signals transmitted from the four GPS satellites 2 are used. Information indicating a time zone during which at least one of the signals cannot be received by the GPS receiver 10 via the antenna 50 may be stored in the prior information storage unit 332 in advance.

  In this case, the reference signal is changed from the first reference signal at a predetermined time before the time (timing) when the arrangement of the GPS satellite 2 that can receive four satellite signals is changed to the arrangement of the GPS satellite 2 that cannot receive one satellite signal. Switch to the second reference signal. In contrast to the above, the reference signal is changed after a predetermined time (timing) when the arrangement of the GPS satellites 2 that cannot receive one satellite signal changes to the arrangement of the GPS satellites 2 that can receive four satellite signals. Switching from the 2 reference signal to the first reference signal. Note that, as described in the first embodiment, the predetermined time may be 0, that is, the predetermined time may not be provided. The predetermined time when the reference signal is switched from the first reference signal to the second reference signal may be the same as the predetermined time when the reference signal is switched from the second reference signal to the first reference signal. May be different.

  According to the timing signal generator 1, the same effects as those of the first embodiment described above can be obtained.

2. Next, an embodiment of an electronic device of the present invention will be described.

FIG. 8 is a block diagram showing an embodiment of the electronic apparatus of the present invention.
8 includes a timing signal generation device 310, a CPU (Central Processing Unit) 320, an operation unit 330, a ROM (Read Only Memory) 340, a RAM (Random Access Memory) 350, a communication unit 360, and a display unit 370. It has.

  The timing signal generation device 310 is, for example, the timing signal generation device 1 in any one of the first embodiment and the second embodiment described above, and receives a satellite signal and has high-accuracy timing as described above. A signal (1PPS) is generated and output to the outside. Thereby, the electronic device 300 with higher reliability at a lower cost can be realized.

  The CPU 320 performs various calculation processes and control processes in accordance with programs stored in the ROM 340 and the like. Specifically, the CPU 320 synchronizes with the timing signal (1PPS) and the clock signal output from the timing signal generator 310, performs various processes according to the operation signal from the operation unit 330, data communication with the outside, and the like. In order to perform the process, a process of controlling the communication unit 360, a process of transmitting a display signal for displaying various information on the display unit 370, and the like are performed.

  The operation unit 330 is an input device including operation keys, button switches, and the like, and outputs an operation signal corresponding to an operation by the user to the CPU 320.

  The ROM 340 stores programs, data, and the like for the CPU 320 to perform various calculation processes and control processes.

  The RAM 350 is used as a work area of the CPU 320, and temporarily stores programs and data read from the ROM 340, data input from the operation unit 330, calculation results executed by the CPU 320 according to various programs, and the like.

  The communication unit 360 performs various controls for establishing data communication between the CPU 320 and an external device.

  The display unit 370 is a display device configured by an LCD (Liquid Crystal Display) or the like, and displays various types of information based on a display signal input from the CPU 320. The display unit 370 may be provided with a touch panel that functions as the operation unit 330.

  Various electronic devices are conceivable as such an electronic device 300, and are not particularly limited. For example, a time management server that realizes synchronization with a standard time (time server), time management that issues time stamps, and the like Examples include devices (time stamp servers) and frequency reference devices such as base stations.

  As mentioned above, although the timing signal generator and electronic device of this invention were demonstrated based on embodiment of illustration, this invention is not limited to this, The structure of each part is arbitrary structures which have the same function Can be substituted. Moreover, other arbitrary components may be added.

  Further, the present invention may be a combination of any two or more configurations (features) of the above embodiments.

  Moreover, in the said embodiment, although the timing signal generator using GPS was mentioned as an example, in this invention, not only GPS but a global navigation satellite system (GNSS) other than GPS, for example, Galileo, GLONASS, etc. May be used.

DESCRIPTION OF SYMBOLS 1 ... Timing signal generator 2 ... GPS satellite 10 ... GPS receiver 11 ... SAW filter 12 ... RF processing part 13 ... Baseband processing part 14 ... TCXO
20. Processing unit 21 ... Phase comparator 22 ... Loop filter 23 ... DSP
24 ... Frequency divider 25 ... GPS control unit 30 ... Crystal oscillator 31 ... Control unit 311 ... Switching timing determination unit 312 ... Threshold storage unit 32 ... Timer 33 ... Prior information output unit 331 ... Information generation unit 332 ... Prior information storage unit 333 ... Time information storage unit 40 ... Temperature sensor 41 ... Building 42 ... Wall part 43 ... Outer surface 50 ... Antenna 121 ... PLL
122 ... LNA
123 ... Mixer 124 ... IF amplifier 125 ... IF filter 126 ... ADC
131 ... DSP
132 ... CPU
133 ... SRAM
134 ... RTC
300 ... Electronic equipment 310 ... Timing signal generator 320 ... CPU
330 ... Operation unit 340 ... ROM
350 ... RAM
360 ... Communication part 370 ... Display part

Claims (11)

An output terminal for outputting a reference signal;
A first reference signal generation unit that generates a first reference signal based on a reference signal input from the outside;
A second reference signal generator that generates a second reference signal based on a signal output from the oscillator;
A control unit that switches the reference signal output from the output terminal from the first reference signal to the second reference signal based on prior information indicating that the accuracy of the reference signal is reduced;
A timing signal generator characterized by comprising:   The timing signal generator according to claim 1, further comprising a prior information output unit that outputs the prior information toward the control unit.   The timing signal generator according to claim 2, wherein the prior information output unit includes a prior information storage unit that stores the prior information.   4. The timing signal generation device according to claim 2, wherein the advance information output unit includes an advance information generation unit that generates the advance information based on the reference signal in advance. A time information storage unit for storing time information;
5. The timing signal generation according to claim 2, wherein the control unit includes a switching timing determination unit that determines a switching timing of the reference signal based on the prior information and the time information. apparatus. The reference signal is a satellite signal transmitted from a position information satellite,
The prior information output unit, as information indicating that the accuracy of the reference signal is decreased, DOP information indicating a relationship between a positioning accuracy decrease rate based on the reference signal and time is directed to the switching timing determination unit. Output,
The timing signal generator according to claim 5, wherein the switching timing determination unit includes a threshold value storage unit that stores a threshold value, and determines the switching timing of the reference signal based on the threshold value and the DOP information. . The oscillator is a voltage controlled oscillator;
The first reference signal generation unit is configured to input a control voltage of the oscillator to the oscillator based on the reference signal when the accuracy reduction rate is equal to or less than the threshold, and to generate the first reference signal,
The control unit obtains information on the control voltage of the oscillator input to the oscillator when the accuracy reduction rate is equal to or less than the threshold, and when the accuracy reduction rate exceeds the threshold, Based on the acquired control voltage information, a control voltage input to the oscillator is obtained, and the obtained control voltage is inputted to the oscillator, whereby the reference signal output from the output terminal is derived from the first reference signal. The timing signal generator according to claim 6, wherein the timing signal generator is switched to the second reference signal. The reference signal is a satellite signal transmitted from a position information satellite,
The timing signal generator according to any one of claims 1 to 7, wherein the first reference signal generator includes a receiver that receives the satellite signal. The prior information includes information indicating that the accuracy of the reference signal is improved,
The timing according to claim 1, wherein the control unit switches the reference signal output from the output terminal from the second reference signal to the first reference signal based on the prior information. Signal generator.   A signal used for generating a reference signal is switched from the reference signal to a signal output from an internal oscillator based on prior information indicating that the accuracy of a reference signal input from the outside is reduced. Timing signal generator.   An electronic apparatus comprising the timing signal generator according to claim 1.

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